This document summarizes the life cycle of stars from birth to death. It discusses how stars like our Sun generate energy through nuclear fusion in their cores and describes the main sequence where most stars lie on the Hertzsprung-Russell diagram. As stars age and exhaust their fuel, they evolve into red giants or white dwarfs and some explode as supernovae at the ends of their lives. Understanding stellar evolution provides insights into the nature and fate of our Sun as well as the potential for life elsewhere.
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Stellar Evolution_Jhon R. Percy.pdf
1. Stellar Evolution:
Birth, Life, and Death of Stars
John R. Percy
International Astronomical Union
University of Toronto, Canada
2. Evolution of stars
⚫ When we talk about stellar evolution
we mean on changes that occur in stars
as they consume "fuel" , since their
birth through their long life, and until
they die.
⚫ Understanding the evolution of stars
help astronomers to understand:
- The nature and future fate of our Sun.
- The origin of our solar system.
- How we compare our solar system with
other planetary systems
- If there could be life elsewhere in the
universe.
The Ring Nebula, a dying star.
Source: NASA
3. Properties of the Sun: the nearest star
and how astronomers measure them – important!
⚫ Distance: 1.5 x 1011 m, reflecting radar
waves from Mercury and Venus
⚫ Mass: 2 x 1030 kg, measuring the
movement of the planets that rotate
around the Sun
⚫ Diameter: 1.4 x 109 m, from the
apparent diameter (angle) of the Sun and
its distance
⚫ Power: 4 x 1026 W, from the distance
and the measured power from Earth
⚫ Chemical composition: 98% hydrogen
and helium, studying its spectrum.
The Sun.
Source: NASA SOHO Satellite
4. Properties of stars – distant suns
and how astronomers measure them – important!
⚫ Distance: from the parallax, or
from the apparent brightness if the
power is known.
⚫ Power: from the distance and
apparent brightness
⚫ Surface temperature: From
the color or spectrum
⚫ Radio: From the power and
surface temperature
⚫ Mass: Using the observations of
binary stars
⚫ Chemical composition:
from stellar spectra
Orion Constellation.
Source: Hubble, ESA, Akira Fujii
5. The spectra of the stars:
starlight, decomposed into colors
⚫ Astronomers learn about
astronomical sources by
studying the light that they
emit
⚫ The spectrum provides
information on the
composition, temperature,
and other properties of stars
Left: the first 13 spectra of stars with different surface
temperatures (the highest on top); the last three spectra
were taken from stars with peculiar properties
Stellar Spectra
Source: US National Optical Astronomy Observatory
6. The Hertzsprung-Russell diagram
There is an order in the properties of stars!
⚫ Most of the stars lie on the
“main sequence”: massive
stars are hot and have high
power (top left), while the
small stars have lower
masses, are cold and have low
power (bottom right)
⚫ The giant stars lie on the top-
right part of the diagram,
while the white dwarfs are on
the bottom-left
Diagram HR Source: NASA
⚫ The Hertzsprung-Russell (HR) diagram, shows the power
(brightness) as a function of temperature (spectral class);
the ordinate "absolute magnitude" is a logarithmic
measure of power.
7. Variable Stars
⚫ Variable stars are stars that
change their brightness
with time
⚫ Most of the stars are
variable; can vary because
they vibrate, shine brightly,
erupt or explode, or are
eclipsed by a companion
star or planet
⚫ Variable stars provide
important information
about the stellar nature and
evolution
Light curve: a graph of brightness vs. time.
8. Binary stars (double) and multiple
⚫ Binary stars are pairs of stars
that are close together due to
gravity, and orbit around
themselves. They can be
visible directly (as in the
image on the left), or
detected by their spectra, or
an eclipse between the stars.
⚫ They are the most important
tool to measure the masses
of stars
⚫ Multiple stars are three or
more stars that are bonded
together due to gravity
Orbital movement of Mizar, in Osa Major.
Source: NPOI Group, USNO, NRL
9. Star clusters
"Experiments of nature”
⚫ Star clusters are groups of
stars that are close each
other due to gravity, and
move all together through
the space
⚫ They were formed at the
same time and place, the
same material, and are at
the same distance, only
differ in the mass
⚫ Clusters are samples of
stars with different masses
but with the same age
Open Cluster The Pleiades.
Source: Mount Wilson Observatory
10. What are the Sun and stars made of?
◼ Using spectroscopy and other techniques, astronomers
can identify the “prime materials” that stars are made of
⚫ Hydrogen (H) and helium (He) are the most abundant
elements, and were formed with the formation of
universe
⚫ Heavier elements are million or billion times less
abundant. They were formed inside the stars through
thermonuclear reactions
Abundances of chemical
elements in the Cosmos:
birdseed H (90%), rice He (8%),
beans C, N, and O and a few of
all the other elements (2%).
11. Elements created at the Big Bang
Elements produced by nucleosynthesis,
in the core of the stars
Elements produced by supernovas
12. The laws of the structure of the stars
⚫ Inside the star, as we go deeper, the pressure
increases due to the weight of upper layers.
⚫ According to the laws of gases, temperature and
density increase as the pressure increases.
⚫ The energy will flow from the inside hotter part to the
outside colder part by radiation and convection.
⚫ If the energy flows out of the star, the star will cool -
unless more energy is created inside.
⚫ The stars are governed by these simple and universal
laws of physics
13. Example: Why the Sun does not
collapse or contract?
⚫ Inflate a balloon as shown
on the left
⚫ The atmospheric pressure is
"pushing" the balloon
inward. It does not shrink
because the gas pressure is
"pushing" the balloon
outward.
⚫ Inside the Sun, gravity,
pushing the material inward,
is balanced by the gas
pressure.
14. The energy source of the Sun and stars
⚫ Chemical combustion of gas, oil or carbon?
This process is so inefficient that bring energy to the Sun
for only a few thousand years
⚫ Slow gravitational contraction?
This could bring energy to the Sun during millions of
years, but the Sun is billions years old
⚫ Radioactivity (nuclear fission)?
Radioactive isotopes are almost non-existent inside the
Sun and stars
⚫ Nuclear fusion of light elements into heavier ones?
Yes! This is a very efficient process, and light
elements such as hydrogen and helium represent
98% of the Sun and stars
15. Proton-Proton chain
is the main process of fusion in the Sun
⚫ At high temperatures and
densities, in stars like our Sun,
protons (in red) overcome the
electrostatic repulsion between
them, and form ²H (deuterium)
and neutrino (ν)
⚫ Later, another proton is coupled
with deuterium to form ³He
⚫ Later, the ³He nuclei are coupled
with each other to form a 4He
nucleus, releasing two protons.
⚫ Result: 4 protons together to form
helium and energy (gamma-rays
and kinetic energy)
Proton-proton cycle
Source: Australia National Telescope Facility
16. The carbon – nitrogen - oxygen cycle
⚫ In massive stars, with very
hot nucleus, protons (red)
can collide with a ¹²C
(carbon) nucleus (top left)
⚫ This begins a circular
sequence of reactions in
which finally four protons
fuse to form a helium
nucleus (top left)
⚫ A ¹²C nucleus is recovered
again at the end of the
cycle, therefore it is not
created nor destroyed; it
acts as a nuclear catalyst
CNO cycle
Source: Australia National Telescope Facility
17. Making stellar “models”
⚫ The laws that describe the stellar
structure are expressed in
equations, and are resolved by
means of a computer
⚫ The computer calculates the
temperature, density, pressure, and
the power at each point of the Sun
or the star. This is called a model
⚫ In the center of the Sun, the density
is 150 times higher than the water
density, and the temperature is
~15,000,000 K!
18. In the interior of the Sun
Based on a "model" of the Sun made with computer
⚫ Inside the hot core, nuclear
reactions produce energy by fusing
hydrogen into helium
⚫ In the radiative zone, above the
nucleus, the energy flows outward
through the mechanism of radiation
⚫ In the convective zone, between the
radiative area and the surface area,
the energy flows outward by
convection
⚫ The photosphere, on the surface, is
the layer where the star becomes
transparent
Solar model
Source: Institute of Theoretical Physics,
University of Oslo
19. Testing helioseismological model
⚫ The Sun vibrates gently in
thousands of ways (patterns).
One of them is shown in the
image on the left
⚫ These vibrations can be
observed and we can use them to
deduce the internal structure of
the Sun, testing therefore the
existing models of Sun’s
structure. This process is known
as helioseismology
⚫ Similar vibrations can be
observed in other stars:
astroseismology
Artistic conception of the solar vibration.
Source: US National Optical Astronomy
Observatory
20. Testing the solar neutrino model
⚫ Nuclear fusion reactions
produce elementary particles
called neutrinos.
⚫ They have very low mass, and
rarely interact with matter.
⚫ Their mass was detected and
measured thanks to special
observatories, such as the
Sudbury Neutrino Observatory
(left). The results are consistent
with the predictions obtained in
models
Observatory of neutrino, Sudbury
Source: Sudbury Neutrino Observatory
21. Duration of the stellar lives
⚫ The duration of the life of a star
depends on how much nuclear fuel
(hydrogen) it has, and how fast
consumes it (power)
⚫ The stars less massive than our Sun
are the most common. They have less
fuel, but much smaller powers, so
they have longer lives
⚫ The stars more massive than the Sun
are less common. They have more
fuel, but powers much higher,
therefore have shorter lives
22. How astronomers learn about stellar
evolution?
⚫ Observing the stars in various stages of their lives, and
putting them in a sequence of logical evolution.
⚫ Making models using computers, using the laws of
physics, and accounting the changes in the composition
of the stars that occur due to nuclear fusion.
⚫ Studying the stellar clusters and/or groups of stars with
different masses, but with the same age.
⚫ Studying the fast and strange phases in stellar lives (e.g.
supernovae and novae).
⚫ Through the study of variable pulsating stars,
measuring the slow changes in the period of pulsation
caused by their evolution.
23. The evolution of Sun-like stars
⚫ When its fuel, hydrogen, exhausts,
it expands into a red giant star.
⚫ Inside the core, the temperatures
can increase enough to start to
produce the energy through the
fusion of helium into carbon.
⚫ When the helium fuel is exhausted,
the star again swells into even
bigger red giant, hundreds of times
bigger than the Sun
Comparison of size: Sun - red giant
Source: Australia National Telescope Facility
⚫ The Sun-like star does not change much during the first
~90% of its life, as far as it has enough fuel (hydrogen)
to continue with thermonuclear reactions. We call it a
main sequence star.
24. The death of Sun-like stars
⚫ When the star becomes a
red giant, it starts to pulsate
(vibrate). We call it Mira
star.
⚫ The pulsation causes the
separation of the outer
layers of the star, producing
a beautiful planetary nebula
(on the left)
⚫ The core of the star is a
dwarf, dense, white, small,
and without fuel
Helix Planetary Nebula.
Source: NASA
25. White dwarf
⚫ A white dwarf presents a dead
core of a Sun-like stars.
⚫ A white dwarf star has a mass
similar to the Sun, a volume
similar to the Earth, and a
density million times greater
than that of the water.
⚫ In a white dwarf, the
centripetal gravitational force
is balanced by the external
quantum pressure of the
electrons in its interior.
⚫ Many nearby stars, including
Sirius (left) and Procyon, have
white dwarf companions.
The white dwarf companion (below) of
Sirius (above). Source NASA
26. The evolution of a massive star
⚫ Massive stars are rare, powerful
and consume their fuel very
quickly - in a few million years.
⚫ When they spent their fuel, they
swell and become red supergiant
stars
⚫ Their core is very hot, enough to
produce heavy elements as iron .
⚫ Betelgeuse (left), in Orion
constellation, is a bright red
supergiant. It is much larger than
the Earth's orbit
Betelgeuse.
Source: NASA/ESA/HST
27. The death of a massive star
⚫ When the core of a massive star
becomes mainly made of iron, it has
no more nuclear fuel to continue with
fusion and can no longer remain hot.
⚫ Gravity crushes the nucleus in a
neutron star, releasing enormous
amounts of gravitational energy, and
leading the star to an explosion of a
supernova (left).
⚫ Supernovae produce elements
heavier than iron, and expel these
and other elements into the space,
which will become part of new stars,
planets and life
The Crab nebula, the remnant of
an explosion of supernovae observed
in 1054 AD. Source: NASA
28. Neutron stars
⚫ The stellar cores with masses
between 1.5 and 3 times the mass of
the Sun collapse and become
neutron stars at the end of the life of
the star.
⚫ They have diameters of about 10
km and densities trillions of times
bigger than water.
⚫ They are made of neutrons and
more exotic particles.
⚫ Young neutron stars rotate rapidly
and emit regular pulses of radiation
in radio, and are known as pulsars.
Pulsar, neutron star in the heart of the
Crab Nebula The rotational energy
that emits energized Nebula.
Source: NASA/ESA/HST
29. Black holes
⚫ A black hole is an astronomical
object whose gravity is so strong
that nothing can escape from it, not
even light.
⚫ The nuclei of the uncommon
massive stars (more than 30 times
the mass of the Sun) become black
holes when their fuel runs out.
⚫ One way of black hole detection:
when a visible star is orbiting
around them (left).
Artistic conception of Cygnus X-1,
a visible star (left) with a black hole
(right) in a center of accretion disk.
Source: NASA.
30. Special cases of variable stars
⚫ Many stellar remnants - white
dwarfs, black holes or neutron
stars - have a normal visible star
orbiting around it.
⚫ If the gas from the normal star
falls to the stellar remnant, the
accretion disk can be formed
around it (left).
⚫ When gas falls on the stellar
remnant, it can burst, erupt, or
explode, which we call a
cataclysmic variable star
A pair of normal star (left) and
a white dwarf star with an accretion disc
stealing gas from the companion (right).
Source: NASA
31. The birth of stars
⚫ Stars are formed inside the
molecular clouds (nebulae), made of
cold gas and dust.
⚫ Interstellar dust and gas is about
10% of the matter in our Galaxy.
⚫ The young stars can generally be
found inside or near the nebula from
which they arose.
⚫ The closest and clear example of a
star formation region is the Orion
nebula (left), around 1500 light years
away from us.
Orion Nebula
Source: NASA
32. Interstellar gas
The gas between the stars
⚫ The interstellar gas (atoms or
molecules) can be activated by
ultraviolet light coming from a
nearby star, producing an
emission nebula (left).
⚫ Cold gas between the stars,
produces radio waves that can
be detected by radio
telescopes.
⚫ 98% of the interstellar gas is
made of hydrogen and helium
The Orion nebula. The gas is energized by
ultraviolet light from the stars in the nebula.
Source: NASA
33. Interstellar dust
Dust between the stars
⚫ Interstellar dust near the bright
stars can be detected in the visible
part of spectra
⚫ Dust can block the light from the
stars and gas behind (left). The
stars are formed in these clouds.
⚫ Only 1% of the material between
the stars is dust. The dust particles
are a few hundred nm in size, and
are mostly silicates or graphite
M16
Soruce: NASA/ESA/HST
34. Star formation
⚫ The stars are formed inside the
parts of a nebula called nuclei,
which are dense or compressed.
⚫ Gravity is responsible for
attraction of nuclei.
⚫ The conservation of angular
momentum increases the
rotation of the nuclei, which
become flattened and finally
convert into the discs.
⚫ Stars are formed in the center of
disks. The planets are formed in
the colder, outer parts of the
disk.
Artistic conception of a planetary system
in the formation process.
Source: NASA
35. Protoplanetary disks: Proplyds
Planetary systems in the process of formation
⚫ Protoplanetary disks have
been observed in the Orion
nebula (left)
⚫ The star can hardly be visible
in the center of the disc.
⚫ The disk of dust blocked the
light that is behind.
⚫ These and other observations
provide a direct evidence of
the formation of planetary
systems.
Proplyds
Source: NASA/ESA/HST
36. Exoplanets = extrasolar planets
Planets around other stars
⚫ The exoplanets are usually
discovered and studied through
gravitational effect they have on
the star, or through the light
dimming of its star if transit occur.
⚫ Very few have been directly
captured (left).
⚫ Unlike the planets in our Solar
System, many exoplanets are huge
and very close to its star. This
allows the astronomers to
modify/correct their theories of
how planetary systems formg.
System exoplanet HR 8799
Source: C. Marois et al., NRC Canada
37. Final considerations
⚫ “Gravity drives the formation, life and death of
stars” [Professor R.L. Bishop]
⚫ The birth of a star explains the origin of our Solar
System and other planetary systems.
⚫ The life of the star explains the energy source that
makes life on Earth possible.
⚫ The life and death of the stars produce chemical
elements heavier than hydrogen, that stars, planets
and life are made of.
⚫ During the death of a star, gravity produces the
strangest objects in the universe: white dwarfs,
neutron stars and black holes.